Project description:Human VECs are categorized into two groups regarding their effects on the proliferation of vascular smooth muscle cells (VSMCs):type-I, pro-proliferative VECs and type-II anti-proliferative VECs. The effects of VECs on VSMC proliferation were quantitatively assessed according to the following method: human aortic smooth muscle cells, which were stained by PKH-26 in advance, were cultured on the layer of CFSE-stained VECs, and VSMC proliferation were evaluated after four days by flow cytometry analyses using ModFit LTM-bM-^DM-" software (Verity Software House Inc., Topsham, ME). Commercially available primary human VECs including HUVEC, HAEC and HMVEC as well as the majority of endothelial progenitor cell (EPC)-derived VECs (EPCdECs), whether EPCs were obtained from adult or fetal tissues, enhanced VSMC proliferation, showing type-I phenotype. EPCdECs of minor donors including EPC1dEC suppressed VSMC proliferation, showing type-II phenotype. However, type-II VECs turned into type-I VECs after a few rounds of subcultures. Comparative analyses on gene expression profiles between type-I VECs and type-II VECs revealed that regulator of G-protein signaling 5 (RGS5) was the only gene that showed the discriminative expression pattern: high expressions in type-I VECs and low expressions in type-II VECs. Totally six samples of type-I VECs (HUVEC, HAEC, HMVEC, EPC1dEC[P12], UCEPC1dEC, EPC2dEC[P7]) and two samples of type-II VECs (EPC1dEC[P7] and EPC1dEC[P7] purchased at a different time point) were subjected to the analyses.

Project description:Human VECs are categorized into two groups according to their effects on the proliferation of vascular smooth muscle cells (in vitro) and the induction of stenosis in endothelia-removed arteries after transplantation (In vivo): pro-proliferative/pro-stenotic (Type-I) virsus anti-proliferative/anti-stenotic (Type-II) VECs. Since RGS5, which is a master gene responsible for aging- and oxidative stress-dependent Type-II to Type-I conversion, is the only protein-coding gene that shows differential expression profiles between Type-I and Type-II VECs, non-coding RNAs including miRNA should be working at the downstream of RGS5 for quality control of VECs.

Project description:Human VECs are categorized into two groups according to their effects on the proliferation of vascular smooth muscle cells (in vitro) and the induction of stenosis in endothelia-removed arteries after transplantation (In vivo): pro-proliferative/pro-stenotic (Type-I) virsus anti-proliferative/anti-stenotic (Type-II) VECs. Since RGS5, which is a master gene responsible for aging- and oxidative stress-dependent Type-II to Type-I conversion, is the only protein-coding gene that shows differential expression profiles between Type-I and Type-II VECs, non-coding RNAs including miRNA should be working at the downstream of RGS5 for quality control of VECs.

Project description:EPC-derived VECs (EPCdECs) are categorized into two group according to their effects on the proliferation of vascular smooth muscle cells: type-I pro-proliferative VECs and type-II anti-proliferative VECs. Type-II EPCdECs were converted to type-I VECs by repetitive subcultures. Not only subculture-dependent cellular stresses but also donor differences greatly affect the phenotype determination of VECs. By comparing the gene expression profiles of type-II EPCdEC of the first donor (EPC1dEC) at early passage and those of type-II EPC1dEC at late passage and EPCdEC of the second donor at early passage, characteristic gene expression patterns that discriminate Type-I and type-II EPCdECs will be comprehended. Totally three samples of type-I EPC-derived VECs (EPC1dEC[P12], EPC2dEC[P7]) and type-II EPC-derived VEC (EPC1dEC[P7]) were subjected to the analyses.

Project description:EPC-derived VECs (EPCdECs) are categorized into two group according to their effects on the proliferation of vascular smooth muscle cells: type-I pro-proliferative VECs and type-II anti-proliferative VECs. Type-II EPCdECs were converted to type-I VECs by repetitive subcultures. Not only subculture-dependent cellular stresses but also donor differences greatly affect the phenotype determination of VECs. By comparing the gene expression profiles of type-II EPCdEC of the first donor (EPC1dEC) at early passage and those of type-II EPC1dEC at late passage and EPCdEC of the second donor at early passage, characteristic gene expression patterns that discriminate Type-I and type-II EPCdECs will be comprehended.

Project description:The gene expression in vascular endothelial cells (VECs) and circulating fibrocytes (CFs) was tested either culturing alone or co-cultured. Our previous study showed that CFs inhibit both proliferation and apoptosis of VECs. In this present study, we co-cultured CFs and VECs in Transwell and tested the gene expression in CFs and VECs in order to delight the mechanism under which CFs affect the proliferation and apoptosis of VECs.

Project description:Differential miRNA expression profiles of human vascular endothelial cells (VECs) between Type-I pro-proliferative/pro-stenotic VECs and Type-II anti-proliferative/anti-stenotic VECs

Project description:The Ca2+/calmodulin-dependent kinase II is expressed in smooth muscle and believed to mediate intracellular calcium handling and calcium-dependent gene transcription. CaMKII is activated by Angiotensin-II. The multifunctional calcium/calmodulin-dependent kinase II (CaMKII) is activated by Angiotensin-II (Ang-II) in vascular smooth muscle cells (VSMC), but its impact on hypertension remains unknown. In our transgenic mice that express the inhibitor peptide CaMKIIN in smooth muscle (TG SM-CaMKIIN), the blood pressure response to chronic Ang-II infusion was significantly reduced as compared to littermate controls. Surprisingly, examination of blood pressure and heart rate under ganglionic blockade revealed a key role for VSMC CaMKII in efferent sympathetic outflow in response to Ang II hypertension. Consistently, the efferent splanchnic nerve activity and plasma phenylephrine concentrations were significantly lower in TG SM-CaMKIIN mice as compared to littermates. Moreover, the aortic depressor nerve activity was reset in hypertensive wild type animals, but not in TG SM-CaMKIIN mice, suggesting that changes in baroreceptor wall activity may be responsible for the blood pressure difference in Ang-II hypertension. The pulse wave velocity, a measure of vascular wall stiffness in vivo, was increased in aortas of hypertensive compared to normotensive WT animals. However, Ang-II infusion did not alter the pulse wave velocity in transgenic mice, suggesting that CaMKII in VSMC controls structural smooth muscle genes. Accordingly, analysis of gene expression changes in aortas from wild type and TG SM-CaMKIIN hypertensive mice demonstrated that CaMKII inhibition mainly altered the expression of muscle contractile proteins. In contrast, TG SM-CaMKIIN aortas were protected from the Ang-II induced upregulation of genes linked to proliferation, suggesting that CaMKII inhibition prevents the Ang-II-induced reprogramming of smooth muscle cell gene expression towards a proliferative phenotype. 5 WT C57Bl/6 and 5 mice that express the Ca2+/calmodulin-dependent kinase II peptide inhibitor CaMKIIN in smooth muscle only (TG SM-CaMKIIN) were infused with 1.25 ug/kg/min Angiotensin-II by osmotic minipump for 14 days. 5 WT and 5 transgenic mice infused with normal saline served as controls. The mice were sacrificed on day 14 and the thoracic aortas isolated. RNA was isolated and pooled for the following groups: WT (wild type), C (TG SM-CaMKIIN), WT-A (WT with Angiotensin-II), C-A (TG SM-CaMKIIN + Angiotensin-II)

Project description:The Ca2+/calmodulin-dependent kinase II is expressed in smooth muscle and believed to mediate intracellular calcium handling and calcium-dependent gene transcription. CaMKII is activated by Angiotensin-II. The multifunctional calcium/calmodulin-dependent kinase II (CaMKII) is activated by Angiotensin-II (Ang-II) in vascular smooth muscle cells (VSMC), but its impact on hypertension remains unknown. In our transgenic mice that express the inhibitor peptide CaMKIIN in smooth muscle (TG SM-CaMKIIN), the blood pressure response to chronic Ang-II infusion was significantly reduced as compared to littermate controls. Surprisingly, examination of blood pressure and heart rate under ganglionic blockade revealed a key role for VSMC CaMKII in efferent sympathetic outflow in response to Ang II hypertension. Consistently, the efferent splanchnic nerve activity and plasma phenylephrine concentrations were significantly lower in TG SM-CaMKIIN mice as compared to littermates. Moreover, the aortic depressor nerve activity was reset in hypertensive wild type animals, but not in TG SM-CaMKIIN mice, suggesting that changes in baroreceptor wall activity may be responsible for the blood pressure difference in Ang-II hypertension. The pulse wave velocity, a measure of vascular wall stiffness in vivo, was increased in aortas of hypertensive compared to normotensive WT animals. However, Ang-II infusion did not alter the pulse wave velocity in transgenic mice, suggesting that CaMKII in VSMC controls structural smooth muscle genes. Accordingly, analysis of gene expression changes in aortas from wild type and TG SM-CaMKIIN hypertensive mice demonstrated that CaMKII inhibition mainly altered the expression of muscle contractile proteins. In contrast, TG SM-CaMKIIN aortas were protected from the Ang-II induced upregulation of genes linked to proliferation, suggesting that CaMKII inhibition prevents the Ang-II-induced reprogramming of smooth muscle cell gene expression towards a proliferative phenotype.

Project description:Angiotensin II (Ang II)-mediated vascular smooth muscle cells (VSMC) dysfunction plays a critical role in cardiovascular diseases. However, the gene expression in this process is unclear. We used Rat Affymetrix gene array to profile Ang II-regulated gene in RVSMC and evaluated their role in VSMC dysfunction. Examined 4 samples of Rat VSMC in triplicate. Control (without Ang II treatment) and 3 samples treated with Ang II for 6h, 12h, and 24h. Compared the changes in gene expression in Ang II treated samples relative to control samples.